US9016428B2

US9016428B2 - Work vehicle and wheel loader

Info

Publication number: US9016428B2
Application number: US14/113,240
Authority: US
Inventors: Yasutaka Numa
Original assignee: Komatsu Ltd
Current assignee: Komatsu Ltd
Priority date: 2013-03-26
Filing date: 2013-03-26
Publication date: 2015-04-28
Anticipated expiration: 2033-03-26
Also published as: US20140291059A1; EP2821607A4; CN104185723A; CN104185723B; EP2821607B1; WO2014155507A1; EP2821607A1; JP5635695B1; JPWO2014155507A1

Abstract

A work vehicle includes an engine, an exhaust gas post-processing device, an engine room and a partitioning member. The exhaust gas post-processing device includes a diesel particulate filtering device, a selective catalyst reduction device, a connecting pipe connecting the diesel particulate filtering and the selective catalyst reduction device, and an injection device configured to inject a reducing agent into the connecting pipe. The engine room accommodates the engine and the exhaust gas post-processing device. The partitioning member includes a first partition part disposed between the injection device and the diesel particulate filtering device, and a second partition part disposed between the injection device and the selective catalyst reduction device.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a U.S. National stage application of International Application No. PCT/JP2013/058708, filed on Mar. 26, 2013.

BACKGROUND

1. Field of the Invention

The present invention relates to a work vehicle and a wheel loader.

2. Background Information

A wheel loader includes an engine room containing an engine to the rear of a cab (see Japanese Laid-Open Patent Publication No. H8-276755). Recently, exhaust gas post-processing devices have been mounted on wheel loaders for processing exhaust gas from the engine. The exhaust gas post-processing device includes mainly a diesel particulate filtering device, and is usually contained inside the engine room.

A hydraulic excavator described in Japanese Laid-open Patent Publication No. 2011-140853 is provided with a selective catalyst reduction device for a nitrogen oxide purifying device as exhaust gas post-processing device. These exhaust gas post-processing devices are typically disposed above the engine to be provided in the exhaust gas path.

SUMMARY

As described above, while the diesel particulate filter is used as the exhaust gas post-processing device, the provision of a selective catalyst reduction device in addition to the diesel particulate filter in the wheel loader is considered to further purify the exhaust gas. In this case, an injection device injects the reducing agent into the exhaust gas flowing inside a connecting pipe that connects the diesel particulate filtering device and the selective catalyst reduction device. As a result, the nitrogen oxides in the exhaust gas exhausted from the engine are reduced to nitrogen.

However, there is a problem that since the diesel particulate filtering device and the selective catalyst reduction device produce heat while operating, the heat from the devices causes the injection device to become hot thus causing a sealing material and the like in the injection device to degrade. A urea aqueous is generally used as the reducing agent to be injected by the injection device. The urea aqueous changes to ammonia when heated. Since ammonia has very strong alkalinity, there is a problem that the durability of the injection device and the like is reduced. This type of problem is not limited to wheel loaders, but also may occur in other work vehicles.

An object of the present invention is to prevent a rise in the temperature of the injection device.

(1) A work vehicle according to a first aspect of the present invention is equipped with an engine, an exhaust gas post-processing device, an engine room, and a partitioning member. The exhaust gas post-processing device includes a diesel particulate filtering device, a selective catalyst reduction device, a connecting pipe, and an injection device. The connecting pipe connects the diesel particulate filtering device and the selective catalyst reduction device. The injection device injects a reducing agent into the connecting pipe. The engine room accommodates the engine and the exhaust gas post-processing device. The partitioning member includes a first partition part and a second partition part. The first partition part is disposed between the injection device and the diesel particulate filtering device. The second partition part is disposed between the injection device and the selective catalyst reduction device.

According to this configuration, since the first partition part of the partitioning member is disposed between the injection device and the diesel particulate filtering device, radiant heat radiating from the diesel particulate filtering device to the injection device can be blocked by the first partition part. According to this configuration, a rise in the temperature of the injection device due to radiant heat from the diesel particulate filtering device can be prevented. Furthermore, since the second partition part of the partitioning member is disposed between the injection device and the selective catalyst reduction device, radiant heat radiating from the selective catalyst reduction device to the injection device can be blocked by the second partition part. Accordingly, a rise in the temperature of the injection device due to radiant heat from the selective catalyst reduction device can be prevented.

(2) The connecting pipe is preferably disposed so that a longitudinal direction thereof is aligned in the vehicle width direction, and the injection device is disposed on a first side of the connecting pipe as seen from the rear.

According to this configuration, the injection device is disposed between the connecting pipe and a vehicle cover. As a result, the area around the injection device is covered by the connecting pipe and the vehicle cover in addition to the abovementioned partitioning member. Consequently, radiant heat radiating from the diesel particulate filtering device and the selective catalyst reduction device can be blocked in a wide area and a rise in the temperature of the injection device can be prevented with more certainty.

(3) The injection device preferably injects the reducing agent at the upstream side of where the exhaust gas flows into the connecting pipe. According to this configuration, the reducing agent can be sufficiently mixed with the exhaust gas inside the connecting pipe.

(4) The diesel particulate filtering device and the selective catalyst reduction device preferably are disposed with the longitudinal directions thereof are aligned in the vehicle width direction.

(5) The injection device is preferably disposed between the diesel particulate filtering device and the selective catalyst reduction device in the front-back direction, and the partitioning member further includes a third partition part disposed above the injection device.

According to this configuration, the injection device is covered by the partitioning member to the front, to the rear, and above. Consequently, radiant heat radiating from the diesel particulate filtering device and the selective catalyst reduction device can be blocked in a wide area and a rise in the temperature of the injection device can be prevented with more certainty.

(6) The work vehicle according to a second aspect of the present invention is equipped with an engine, an exhaust gas postprocessing device, an engine room, and a partitioning member. The exhaust gas post-processing device includes a diesel particulate filtering device, a selective catalyst reduction device, a connecting pipe, and an injection device. The connecting pipe connects the diesel particulate filtering device and the selective catalyst reduction device. The injection device injects a reducing agent into the connecting pipe. The engine room accommodates the engine and the exhaust gas post-processing device. The partitioning member includes a first partition part and a second partition part. The first partition part is disposed between the injection device and the diesel particulate filtering device. The second partition part is disposed between the injection device and the selective catalyst reduction device.

According to this configuration, since the first partition part of the partitioning member is disposed between the injection device and the diesel particulate filtering device, radiant heat radiating from the diesel particulate filtering device to the injection device can be blocked by the first partition part. As a result, a rise in the temperature of the injection device due to radiant heat from the diesel particulate filtering device can be prevented. Furthermore, since the second partition part of the partitioning member is disposed between the injection device and the selective catalyst reduction device, radiant heat radiating from the selective catalyst reduction device to the injection device can be blocked by the second partition part. Accordingly, a rise in the temperature of the injection device due to radiant heat from the selective catalyst reduction device can be prevented.

According to the present invention, a rise in temperature of the injection device can be prevented.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of the wheel loader as seen from the left rear.

FIG. 2 is a side cross-section of the rear vehicle body as seen from the left side.

FIG. 3 is a perspective view of the exhaust gas post-processing device as seen from the left rear.

FIG. 4 is a perspective view of a detail around an injection device as seen from the right front.

FIG. 5 is a plan view of the detail around an injection device.

FIG. 6 is a plan view of the rear vehicle body when the top plate is removed.

FIG. 7 is a perspective view of the top plate part as seen from the left rear.

FIG. 8 is a cross-section of the left side of the top plate part as seen from the rear.

FIG. 9 is a side cross-section of a drainage mechanism as seen from the left side.

FIG. 10 is a perspective view of the drainage mechanism as seen from the right rear.

FIG. 11 is a perspective view of a water conveyance member disposed on the left side as seen from the right rear.

DETAILED DESCRIPTION OF EMBODIMENTS

An embodiment of a wheel loader according to the present invention will be explained below with reference to the drawings. FIG. 1 is a perspective external view of a wheel loader 1 as seen from the left rear. In the following explanation, “front” and “rear” refer to the front and the rear of a vehicle body 3. In the following explanation, “right,” “left,” “up,” and “down” indicate directions relative to a state of looking forward from the operating cabin, and “vehicle width direction” and “crosswise direction” have the same meaning. Further, “width” signifies a length in the crosswise direction.

As illustrated in FIG. 1, the wheel loader 1 includes working equipment 2, the vehicle body 3, front wheels 4, and rear wheels 5. The wheel loader 1 is capable of traveling due to the rotation of the front wheels 4 and the rear wheels 5, and desired work can be conducted using the working equipment 2.

The working equipment 2 is a mechanism driven by operating fluid pressurized by a hydraulic pump, and is disposed at the front of the vehicle body 3. The working equipment 2 includes a bucket 2 a, a boom (not shown), a lift cylinder (not shown), and a bucket cylinder 2 b. The bucket 2 a is attached to the tip of the boom. The boom is a member for lifting the bucket 2 a and is mounted at the front part of a below mentioned front vehicle body 3 a. The lift cylinder drives the boom with pressure oil discharged from a working equipment pump. The bucket cylinder 2 b drives the bucket 2.a with pressure oil discharged from the working equipment pump.

The vehicle body 3 includes the front vehicle body 3 a and a rear vehicle body 3 b. The front vehicle body 3 a and the rear vehicle body 3 b are coupled to each other in a manner that allows swinging in the crosswise direction. The working equipment 2 and the front wheels 4 are provided on the front vehicle body 3 a, and the rear wheels 5 are provided on the rear vehicle body 3 b.

The rear vehicle body 3 b includes a rear frame 6, a cab 7, an operating fluid tank 8, an engine room 9, a cooling room 10, and a cooling fan 11. The rear frame 6 is a frame that constitutes the entire shape of the rear vehicle body 3 b, and supports the rear wheels 5, the cab 7, the operating fluid tank 8, an engine 12 (see FIG. 2), and a cooling unit 18 (see FIG. 2).

An operating cabin is provided inside the cab 7, and various operating members and an operating panel are provided inside the cab 7. The operating fluid tank 8 is disposed to the rear of the cab 7, and a plurality of hydraulic pumps (not shown) are disposed below the operating fluid tank 8. Operating fluid for driving the working equipment 2 and the like is accumulated in the operating fluid tank 8, and the operating fluid is supplied to the working equipment 2 and the like by the hydraulic pumps.

FIG. 2 is a side cross-section of the rear vehicle body 3 b as seen from the left rear. As illustrated in FIG. 2, the engine room 9 is disposed to the rear of the operating fluid tank 8, and has a front plane defined by the operating fluid tank 8, side planes defined by a vehicle cover 9 a (see FIG. 1), a rear plane defined by a partition wall 9 b, and an upper plane defined by a top plate 9 c.

The engine room 9 accommodates the engine 12 and an exhaust gas post-processing device 13. The engine room 9 further accommodates a belt 12 a and the like for transmitting torque from the engine 12 to auxiliary equipment. The engine 12 is disposed in a lower part of the engine room 9 and is an engine in which the crankshaft extends in the front-hack direction, that is, a so-called vertical mounted engine.

The exhaust vas post-processing device 13 accommodated in the engine room 9 is disposed in an upper part of the engine room 9. Specifically, the exhaust vas post-processing device 13 is disposed above the engine 12. FIG. 3 is a perspective view of the exhaust gas post-processing device 13 as seen from the left rear. As illustrated in FIG. 3, the exhaust gas post-processing device 13 includes, in order of the flow of the exhaust gas, a diesel particulate filtering device 13 a, a connecting pipe 13 b, and a selective catalyst reduction device 13 c. An injection device 14 is attached to the connecting pipe 13 b.

The diesel particulate filtering device 13 a is coupled to the engine 12 via a pipe 13 d, and treats exhaust gas emitted from the engine 12. Specifically, the diesel particulate filtering device 13 a is a device that collects, in a filter, particulate matter such as soot in the exhaust gas emitted from the engine 12. The diesel particulate filtering device 13 a burns the collected particulate matter with a heater provided with the filter. The diesel particulate filtering device 13 a is mounted on a supporting member and the like attached to the rear frame 6.

The connecting pipe 13 b connects the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c. The connecting pipe 13 b has a first bend section 13 e, a linear section 13 f, and a second bend section 13 g, and the entire connecting pipe 13 b forms an S shape. The first bend section 13 e is connected to an exhaust gas outlet 13 h of the diesel particulate filtering device 13 a, and the second bend section 13 g is connected to an exhaust gas inlet 13 i of the selective catalyst reduction device 13 c. The linear section 13 f extends between the first bend section 13 e and the second bend section 13 g. The longitudinal direction of the connecting pipe 13 b is disposed so as to be aligned in the vehicle width direction. The direction in which the linear section 13 b extends is the longitudinal direction of the connecting pipe 13 b.

The injection device 14 is disposed on the right side (example of a first side) of the connecting pipe 13 b. That is, the injection device 14 is attached to the right side surface of the first bend section 13 e. The injection device 14 is a device that injects a urea aqueous solution, which is fed from a urea aqueous solution tank (not shown) disposed on the outside of the engine room 9 and through a urea aqueous solution pipe 14 a (see FIG. 4), into the connecting pipe 13 b in order to mix the urea aqueous solution into the exhaust gas as a reducing agent. The mixed urea aqueous solution is hydrolyzed to become ammonia, and the ammonia is fed with the exhaust gas through the connecting pipe 13 b to the selective catalyst reduction device 13 c.

The selective catalyst reduction device 13 c is a device that uses the urea aqueous solution from the urea water injection device 14 as the reducing agent to purify by reduction the nitrogen oxides in the exhaust gas. The selective catalyst reduction device 13 c is mounted on a supporting member and the like in the same way as the diesel particulate filtering device 13 a.

The diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c are disposed parallel to each other. Specifically, the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c are both substantially cylindrical. The direction that the center axes of the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c extends is the longitudinal direction of the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c. The longitudinal direction of the devices extends substantially parallel to each other in the crosswise direction. The linear section 13 f of the connecting pipe 131) is also substantially cylindrical and the longitudinal direction extends in the crosswise direction as described above. Specifically, the center axis of the linear section 13 f in the connecting pipe 13 b is substantially parallel to the center axes of the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c.

FIG. 4 is a perspective view of a detail around the injection device 14 as seen from the right front, and FIG. 5 is a plan view of the detail around the injection device 14. As illustrated in FIGS. 4 and 5, a partitioning member is disposed so as to cover the injection device 14 in the front, the rear, and from above. The partitioning member includes a first partition plate 16 and a second partition plate 17. The first partition plate 16 and the second partition plate 17 are disposed in a row in the front-back direction. The first partition plate 16 is disposed in front of the second partition plate 17. A partition plate is divided into two to constitute the first partition plate 16 and the second partition plate 17, and an interval between the first partition plate 16 and the second partition plate 17 is provided to create a gap for pipes and the like to pass through.

The first partition plate 16 has a base part 16 a and a peripheral wall part 161, and is fixed to the rear frame 6 using a mounting bracket 6 a and bolts 6 b. The first partition plate 16 has heat shielding properties and is formed, for example, by a steel plate treated with a heat resistant coating. The base part 16 a of the first partition plate 16 is a plate that extends in the front-back direction from the front edge part of the engine room 9 to near the injection device 14, and has a substantially rectangular. A rear edge part of the base part 16 a is cut into a fan shape so that the right side surface of the injection device 14 is exposed when the vehicle cover 9 a is removed. That is, the base part 16 a does not extend to the side of the injection device 14.

The base part 16 a is disposed between the selective catalyst reduction device 13 c and the vehicle cover 9 a. The urea aqueous solution pipe 14 a extends between the base part 16 a and the vehicle cover 9 a. Thus, radiant heat radiating toward the urea aqueous solution pipe 14 a from the selective catalyst reduction device 13 c can be blocked and consequently the urea aqueous solution flowing inside the urea aqueous solution pipe 14 a can be prevented from changing to ammonia. Further, radiant heat radiating toward the vehicle cover 9 a from the selective catalyst reduction device 13 c can be blocked and consequently damage to the coating of the vehicle cover 9 a can be prevented. The urea aqueous solution pipe 14 a is supported by a plurality of mounting brackets 6 c. The urea aqueous solution pipe 14 a is supported by the mounting brackets 6 c to maintain a certain distance from the first partition plate 16. The mounting brackets 6 c extend upward from the rear frame 6 and are slanted in a direction away from the first partition plate 16. The mounting brackets 6 c are disposed a certain distance away from each other in the front-back direction.

The peripheral wall part 16 b of the first partition plate 16 extends from the rear edge of the base part 16 a toward the left side and covers the injection device 14 from the front thereof to above the injection device 14 so as to face the injection device 14. That is, the peripheral wall part 16 b has a second partition part 16 b 1 that is a portion disposed between the injection device 14 and the selective catalyst reduction device 13 c, and a third partition part 16 b 2 that is a portion disposed between the injection device 14 and the top plate 9 c. The peripheral wall part 16 b extends from the base part 16 a to near the right side surface of the connecting pipe 13 b. The peripheral wall part 16 b also extends substantially along the contour of the right side surface of the connecting pipe 13 b. As a result, the left side, the front side, and the top of the injection device 14 can be covered by the peripheral wall part 16 b and the right side surface of the connecting pipe 13 b.

The second partition plate 17 has a base part 17 a and a peripheral wall part (example of a first partition part) 17 b, and is fixed to the vehicle cover 9 a using bolts and the like. The vehicle cover 9 a is divided into a plurality of portions and each of the portions can be opened and closed independently in order to facilitate access to the inside parts (engine room 9 and cooling room 10) of the rear vehicle body 3 b. The portion of the vehicle cover 9 a supporting the second partition plate 17 is fixed to the rear frame 6 via a hinge at the front edge part of the engine room and can be opened and closed around the hinge (see FIG. 7). Maintenance of the injection device 14 and the like is facilitated since the second partition plate 17 is also pulled away when the vehicle cover 9 a is opened. The second partition plate 17 has heat shielding properties and is formed, for example, by a steel plate treated with a heat resistant coating.

The base part 17 a of the second partition plate 17 is a plate that extends in the front-back direction from near the injection device 14 to the rear edge part of the engine room 9, and has a rectangular shape. The front edge of the base part 17 a is located to the rear of the injection device 14. The base part 17 a is disposed between the diesel particulate filtering device 13 a and the vehicle cover 9 a. As a result, radiant heat radiating toward the vehicle cover 9 a from the diesel particulate filtering device 13 a can be blocked and consequently damage to the coating of the vehicle cover 9 a can be prevented.

The peripheral wall part 17 b of the second partition plate 17 extends from the front edge of the base part 17 a toward the left side and covers the injection device 14 from the rear thereof so as to face the injection device 14. That is, the peripheral wall part 17 b is disposed between the injection device 14 and an exhaust gas outlet 13 h of the diesel particulate filtering device 13 a. The peripheral wall part 17 b extends from the base part 17 a to near the right side surface of the connecting pipe 13 b.

As described above, the injection device 14 is disposed in an accommodating space S defined by the peripheral wall part 16 b of the first partition plate 16, the peripheral wall part 17 b of the second partition plate 17, the vehicle cover 9 a, and the connecting pipe 13 b.

As illustrated in FIG. 2, the cooling room 10 is disposed to the rear of the engine room 9, and the cooling unit 18 is accommodated inside the cooling room 10. The cooling unit 18 is a unit for reducing the temperature of liquids or gases flowing inside the cooling unit 18, and may be exemplified by a condenser or a radiator and the like. The cooling room 10 has a front plane defined by the partition wall 9 b, side planes defined by the vehicle cover 9 a, and a rear plane defined by a grille 21. Further, the upper plane of the cooling room 10 is defined by the top plate 9 c. Air inside the cooling room 10 is exhausted to the outside in the rear through an opening part of the grille 21 due to the cooling fan 11 being rotated.

FIG. 6 is a plan view of the rear vehicle body 3 b when the top plate 9 c is removed. As illustrated in FIG. 6, a first exhaust pipe 19 and a second exhaust pipe 20 are disposed so as to straddle the engine room 9 and the cooling room 10. The first exhaust pipe 19 is a substantially linear pipe having one end 19 a and another end 19 b. The one end 19 a of the first exhaust pipe 19 is located in the engine room 9, and the another end 19 b of the first exhaust pipe 19 is located in the cooling room 10. The first exhaust pipe 19 passes through the partition wall 9 b to extend in the front-back direction on the right side and above the engine room 9 and the cooling room 10.

Specifically, the one end 19 a of the first exhaust pipe 19 is located near the injection device 14. One end part 19 c that includes the one end 19 a of the first exhaust pipe 19 bends toward the outside. Consequently, the one end 19 a of the first exhaust pipe 19 is disposed to face the accommodating space S that accommodates the injection device 14. The one end 19 a of the first exhaust pipe 19 is located near enough to the injection device 14 to allow air inside the accommodating space S to be sucked in. Specifically, the one end 19 a is preferably located above an attachment part of the injection device 14 to the connecting pipe 13 b, or more preferably the one end 19 a is located inside the accommodating space S.

The another end 19 b of the first exhaust pipe 19 is located between the cooling fan 11 and the cooling unit 18. Another end part 19 d that includes the another end 19 b of the first exhaust pipe 19 bends downward and bends to the inside so that the another end 19 b of the first exhaust pipe 19 is located between the cooling fan 11 and the cooling unit 18. The cooling fan 11 produces an air flow toward the rear. Specifically, the cooling fan 11 sucks air from the front side (one side) of the cooling fan 11 and exhausts air from the rear side (another side) of the cooling fan 11. Since the cooling unit 18 is disposed on the front side of the cooling fan 11, negative pressure occurs between the cooling fan 11 and the cooling unit 18. As a result, when the cooling fan 11 is operating, the first exhaust pipe 19 acts to suck in air from the one end 19 a and exhaust air from the another end 19 b. Specifically, the first exhaust pipe 19 sucks in the air in the accommodating space S and exhausts the air to the outside through the cooling fan 11.

The second exhaust pipe 20 is a substantially linear pipe having one end 20 a and another end 20 b. The one end 20 a of the second exhaust pipe 20 is located in the engine room 9, and the another end 20 b of the second exhaust pipe 20 is located in the cooling room 10. The second exhaust pipe 20 passes through the partition wall 9 b to extend in the front-back direction on the left side and above the engine room 9 and the cooling room 10.

The one end 20 a of the second exhaust pipe 20 is disposed above the connecting pipe 13 b. The one end 20 a of the second exhaust pipe 20 is disposed between the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c as seen in the plan view. One end part 20 c that includes the one end 20 a of the second exhaust pipe 20 bends toward the inside. Consequently, the one end 20 a of the second exhaust pipe 20 is located near the center in the vehicle width direction.

The another end 20 b of the second exhaust pipe 20 is located between the cooling fan 11 and the cooling unit 18. Another end part 20 d that includes the another end 20 b of the second exhaust pipe 20 bends downward and to the inside so that the another end 20 b of the second exhaust pipe 20 is located between the cooling fan 11 and the cooling unit 18. Since negative pressure occurs between the cooling fan 11 and the cooling unit 18 as described above, the second exhaust pipe 20 sucks in air from the one end 20 a and exhausts air from the another end 20 b.

FIG. 7 is a perspective view of the top plate 9 c as seen from the left rear. As illustrated in FIG. 7, the to plate 9 c is fixed in a removable manner with screws and the like to the upper end part of the vehicle cover 9 a. The top plate 9 c is a plate-like member having a front part that projects upward, and includes a flat part 9 d, a first sloping part 9 e (example of a sloping part), a pair of side wall parts 9 f, a front wall part 9 n (see FIG. 2), and a second sloping part 9 g.

The flat part 9 d is rectangular, extends substantially horizontally, and defines the front part upper plane of the engine room 9. An exhaust pipe 9 h extends upward from the flat part 9 d. The exhaust pipe 9 b is a pipe for exhausting the exhaust gas that has been processed from the exhaust gas post-processing device 13 to the outside. As illustrated in FIG. 2, the front wall part 9 n extends from the front edge of the flat part 9 d downward toward the vehicle cover 9 a.

As illustrated in FIG. 7, the first sloping part 9 e extends to the rear from the rear edge of the flat part 9 d, and the height decreases towards the rear. The first sloping part 9 e has the same width as the flat part 9 d and defines the rear part upper plane of the engine room 9. The first sloping part 9 e has a first ventilation part 9 i made up of a plurality of through-holes. Air inside the engine room 9 is exhausted to the outside, and outside air is sucked into the engine room 9 through the first ventilation part 9 i. The through-holes that constitute the first ventilation part 9 i have a slit shape.

The pair of side wall parts 9 f extends downward from both edges of the flat part 9 d and the first sloping part 9 e toward the vehicle cover 9 a. The side wall parts 9 f each have a flange part 9 p at the lower edges. The side wall parts 9 f each have a second ventilation part 9 j made up of a plurality of through-holes. Air inside the engine room 9 is exhausted to the outside, and outside air is sucked into the engine room 9 through the second ventilation parts 9 j. The through-holes that constitute the second ventilation parts 9 j have a slit shape.

FIG. 8 is a cross-section of the left side of the side wall part 9 f as seen from the rear. As illustrated in FIG. 8, the through-holes that constitute the second ventilation parts 9 j each have an cave part 9 k at the upper part. By providing each of the through-holes with the cave part 9 k at the upper part since the side wall parts 9 f substantially extend vertically, liquid such as rainwater can be prevented from entering the engine room 9.

As illustrated in FIG. 7, a projecting part at the front of the top plate 9 c is configured by the abovementioned flat part 9 d, the first sloping part 9 e, the pair of side wall parts 9 f, and the front wall part 9 n. The capacity of the engine room 9 is increased by the amount of the space enclosed by the flat part 9 d, the first sloping part 9 e, the pair of side wall parts 9 f, and the front wall part 9 n.

The second sloping part 9 g extends to the rear from the rear edges of the first sloping part 9 e and the flange parts 9 p. The height of the vehicle cover 9 a decreases toward the rear, and the second sloping part 9 g slopes along the upper edge of the rear part of the vehicle cover 9 a. Specifically, the height of the second sloping part 9 g decreases toward the rear. The slope of the second sloping part 9 g is gentler than the slope of the first sloping part 9 e.

The second sloping part 9 g mainly defines an upper plane of the cooling room 10, and partially defines the rear part upper plane of the engine room 9. The second sloping part 9 g has an intake part 9 m made up of a plurality of through-holes. When the cooling fan 11 is operating, air inside the cooling room 10 is exhausted to the outside through an opening part of the grille 21, and outside air is sucked into the cooling room 10 through the intake part 9 m. Further, air from the outside flows into the cooling room 10 through an intake part 9 q formed in the vehicle cover 9 a.

FIG. 9 is a side cross-section of a drainage mechanism 15 disposed inside the rear vehicle body 3 b as seen from the left side. To facilitate explanation, the description of the first exhaust pipe 19 is omitted in FIG. 9. As illustrated in FIG. 9, the drainage mechanism 15 is disposed inside the engine room 9. The drainage mechanism 15 includes a receptacle member 15 a and a water conveyance member 15 b.

The receptacle member 15 a is disposed below the first ventilation part 9 i of the first sloping part 9 e, and is a tray-like member that receives rainwater and the like that enters the engine room 9 from the first ventilation part 9 i. The receptacle member 15 a has a rectangular bottom plate 15 c and a side plate 15 d that extend upward from the outer edges of the bottom plate 15 c. The width of the receptacle member 15 a is the same or greater than the width of the first ventilation part 9 i so as to be able to receive all the rainwater entering through the first ventilation part 9 i, and is preferably approximately the same width as the engine room 9. The front edge of the receptacle member 15 a is located at the front edge of the first ventilation part 9 i or located further forward than the front edge of the first ventilation part 9 i. The rear edge of the receptacle member 15 a is located at the rear edge of the first ventilation part 9 i or further to the rear of the rear edge of the first ventilation part 9 i, and is preferably located near the partition wall 9 b. The bottom plate 15 c is disposed in a sloped manner so that the height of the bottom plate 15 c is lower further toward the rear in order to allow the rainwater received by the receptacle member 15 a to flow to the rear.

FIG. 10 is a perspective view of the drainage mechanism 15 as seen from the right rear, and FIG. 11 is a perspective view of the water conveyance member 15 b disposed on the left side as seen from the right rear. To facilitate explanation, the description of the second sloping part 9 g on the top plate 9 c, and the first and

second exhaust pipes

19 and 20 are omitted in FIGS. 10 and 11. As illustrated in FIG. 10, the bottom plate 15 c of the receptacle member 15 a, has through-holes 15 e at a left rear edge part and at a right rear edge part. The water conveyance members 15 b are disposed below each of the through-holes 15 e. The water conveyance member 15 b disposed on the left side of the engine room 9 and the water conveyance member 15 b disposed on the right side of the engine room 9 have symmetrical shapes relative to the center in the vehicle width direction, and therefore only an explanation of the water conveyance member 15 b disposed on the left side will be provided hereinbelow.

The water conveyance member 15 b is a member that guides rainwater that drips from the through-holes 15 e of the receptacle member 15 a to the outside of the engine room 9. As illustrated in FIGS. 9 and 11, the water conveyance member 15 b has a bottom plate 15 f and a side plate 15 g. The bottom plate 15 f is rectangular, and the left edge of the bottom plate 15 f is fitted to the vehicle cover 9 a, and the rear edge of the bottom plate 15 f is fitted to the partition wall 9 b. The side plate 15 g extend upward from the front edge and the right edge of the bottom plate 15 f. Specifically, the water conveyance member 15 b is a vessel-shaped member that is open at the upper plane, and the lower plane is defined by the bottom plate 15 f and the side planes are defined by the side plate 15 g, the vehicle cover 9 a, and the partition wall 9 b.

The partition wall 9 b is a plate-like member for separating the engine room 9 and the cooling room 10, and has notch-like water drainage outlets 9 r at a right upper edge part and at a left upper edge part. The upper edge of each water drainage outlet 9 r is located higher than the bottom plate 15 f of the water conveyance member 15 b, and the bottom edge of each water drainage outlet 9 r is located lower than the upper edge of the side plates 15 g. The water conveyance member 15 b is disposed in a sloped manner so that the height of the bottom plate 15 f is lower further toward the rear in order to allow the rainwater received by the receptacle member 15 a to flow to the rear. As a result, the rainwater that drips off of the receptacle member 15 a into the water conveyance members 15 b flows to the rear and is discharged through the water drainage outlets 9 r of the partition wall 9 b toward the cooling room 10.

The receptacle member 15 a is located below the first sloping part 9 e as illustrated in FIG. 2. The receptacle member 15 a is located above the diesel particulate filtering device 13 a. The receptacle member 15 a has heat insulation properties. For example, the receptacle member 15 a may be formed of a steel plate treated with a heat insulating coating, may be formed of aluminum, an aluminum alloy, or stainless steel, or may be coated with a coating including aluminum, an aluminum alloy, or stainless steel. The transmission of radiant heat from the diesel particulate filtering device 13 a to the top plate 9 c can be suppressed by the receptacle member 15 a that is disposed between the diesel particulate filtering device 13 a and the top plate 9 c. In this way, the receptacle member 15 a functions as a heat insulating plate.

The wheel loader 1 according to the present embodiment has the following characteristics.

(1) Since the second partition part 16 b 1 of the peripheral wall part 16 b of the first partition plate 16 is disposed between the injection device 14 and the selective catalyst reduction device 13 c, radiant heat radiating from the selective catalyst reduction device 13 c to the injection device 14 can be blocked. Accordingly, a rise in the temperature of the injection device 14 due to radiant heat from the selective catalyst reduction device 13 c can be prevented. Further, since the peripheral wall part 17 b of the second partition plate 17 is disposed between the injection device 14 and the diesel particulate filtering device 13 a, radiant heat from the diesel particulate filtering device 13 a to the injection device 14 can be blocked. According to this configuration, a rise in the temperature of the injection device 14 due to radiant heat from the diesel particulate filtering device 13 a can be prevented.

(2) The injection device 14 is disposed between the connecting pipe 13 b and the vehicle cover 9 a. As a result, the area around the injection device 14 is covered by the connecting pipe 13 b and the vehicle cover 9 a in addition to the

peripheral wall parts

16 b and 17 b of the abovementioned first and

second partition plates

16 and 17. Consequently, radiant heat radiating from the diesel particulate filtering device 13 a and the selective catalyst reduction device 13 c can be blocked in a wide area and a rise in the temperature of the injection device 14 can be prevented with more certainty.

(3) The injection device 14 injects the reducing agent at the upstream side where the exhaust gas flows into the connecting pipe 13 b. According to this configuration, the reducing agent can be sufficiently mixed with the exhaust gas inside the connecting pipe 13 b.

(4) The front, rear and the top of the injection device 14 is covered by the respective

peripheral wall parts

16 b and 17 b of the first and

second partition plates

(5) The another end 19 b of the first exhaust pipe 19 is located between the cooling unit 18 and the cooling fan 11 which is a region of negative pressure when the cooling fan 11 is operating. As a result, the first exhaust pipe 19 acts to suck in the air around the injection device 14 from the one end 19 a and to exhaust the air from the another end 19 b. Consequently, the area around the injection device 14 in the engine room 9 has negative pressure, and the air taken in from outside of the engine room 9, for example, through the first and

second ventilation parts

9 i and 9 j of the top plate 9 c flows around the injection device 14. As a result, the injection device 14 is cooled by the cooling air that flows from the outside toward the one end 19 a of the first exhaust pipe 19. The front and rear of the injection device 14 is covered by the respective

peripheral wall parts

16 b and 17 b of the first and

second partition plates

16 and 17. As a result, the one end 19 a of the first exhaust pipe 19 is able to effectively suck in air around the injection device 14 and accordingly is able to further cool the injection device 14.

MODIFIED EXAMPLES

While an embodiment of the present invention has been described above, the present invention is not limited to the embodiment and many variations and modifications can be made within the spirit of the present invention.

Modified Example 1

While the partitioning member is configured of two partition plates being the first partition plate 16 and the second partition plate 17 in the above embodiment, the number of partition plates that configure the partitioning member is not limited as such and the partitioning member may be configured of one partition plate or may be configured of three or more partition plates. Specifically, the injection device 14 may be covered by one partition plate or may be covered by three or more partition plates.

Modified Example 2

The front, rear and the top of the injection device 14 is covered by, hut not limited to, the respective

peripheral wall parts

16 b and 17 b of the first and

second partition plates

16 and 17 in the above embodiment. For example, the front, the rear, the top, and the bottom of the injection device 14 may be covered by the respective

peripheral wall parts

16 b and 17 b of the first and

second partition plates

16 and 17, and further the right side of the injection device 14 may also be covered.

Modified Example 3

While two pipes being the first exhaust pipe 19 and the second exhaust pipe 20 are installed in the above embodiment, the second exhaust pipe 20 may be omitted and only the first exhaust pipe 19 may be installed, or both the first exhaust pipe 19 and the second exhaust pipe 20 may be omitted.

Modified Example 4

While the first and

second ventilation parts

9 i and 9 j are formed in the top plate 9 c to pull in outside air into the engine room 9 in the above embodiment, the present invention is not limited as such. For example, a ventilation part may be formed in the vehicle cover 9 a that defines the side surface of the engine room 9 instead of being formed in the top plate 9 c, in this case, forming the ventilation part in a region of the vehicle cover 9 a facing the injection device 14 is desired from the point of view of effectively cooling the injection device 14.

Modified Example 5

While an example of a wheel loader has been explained in the above embodiment, the present invention may be applicable to another work vehicle.

Claims

The invention claimed is:

1. A work vehicle comprising:

an engine;

an exhaust gas post-processing device including

a diesel particulate filtering device,

a selective catalyst reduction device,

a connecting pipe connecting the diesel particulate filtering device and the selective catalyst reduction device, and

an injection device configured to inject a reducing agent into the connecting pipe;

an engine room accommodating the engine and the exhaust gas post-processing device; and

a partitioning member having a first partition plate and a second partition plate arranged separated from each other by a gap in a front-back direction of the work vehicle, the second partition plate including a first partition part disposed between the injection device and the diesel particulate filtering device, and the first partition plate including a second partition part disposed between the injection device and the selective catalyst reduction device, the partitioning member being separated by a gap from each of the diesel particulate filter, the selective catalyst reduction device, the connecting pipe, and the injection device.

2. The work vehicle according to claim 1, wherein

the connecting pipe is disposed so that a longitudinal direction thereof is aligned with a vehicle width direction, and

the injection device is disposed on a first side of the connecting pipe as seen from the rear.

3. The work vehicle according to claim 2, wherein

the injection device is configured to inject the reducing agent at an upstream side of where exhaust gas flows into the connecting pipe.

4. The work vehicle according to claim 1, wherein

the diesel particulate filtering device and the selective catalyst reduction device are disposed with longitudinal directions thereof being aligned with a vehicle width direction.

5. The work vehicle according to claim 1, wherein

the injection device is disposed between the diesel particulate filtering device and the selective catalyst reduction device in a front-back direction of the work vehicle, and

the partitioning member includes a third partition part disposed above the injection device.

6. The work vehicle according to claim 1, wherein

the first and second partition parts have heat shielding properties.

7. The work vehicle according to claim 1, wherein

a vehicle cover defining a side plane of the engine room, the first partition part being fixed to the vehicle cover.

8. A wheel loader comprising:

a plurality of wheels;

an engine;

an exhaust gas post-processing device including

a diesel particulate filtering device,

a selective catalyst reduction device,